Using Marie vacuum residue as raw material, the acetic acid⁃peroxyacetic acid oxidation system was used to pre⁃oxidize the vacuum residue, and N, N⁃dimethylformamide (DMF) was used to extract and remove sulfide in the residue. Under the conditions of m(residue)/m(solvent)=1 ∶ 1, Investigate the effects of oxidant dosage, reaction time and temperature on the removal of sulfur content in residue oil. X⁃ray photoelectron spectroscopy (XPS) and Fourier infrared spectrometer (FT⁃IR) The organic sulfur type distribution and functional groups of the residual oil before and after oxidation were detected. The results show that under the conditions of m(residue oil)/m(solvent)/m(acetic acid⁃peroxyacetic acid)=5 ∶ 5 ∶ 4, oxidation temperature 70 ℃, and oxidation time 50 minutes, the C-S stretching vibration absorption peak of the oxidized residue is obviously weakened. Thiophene type sulfur can be removed by extraction after being oxidized to sulfones. The sulfur content of the residue is reduced from 4.01% to 2.67%, the desulfurization rate reaches 33.37%, and the residue yield is 94.82%.

Photoelectrocatalytic technology can provide an energy conservation and environmental protection way for environmental governance and chemical production. High efficient photoanodes materials are one of the challenges in the practical application of photoelectrocatalytic technique, therefore, high performance photoanode materials have been designed and developed for enhancing the application efficiency of photoelectrocatalytic technique. Fe2O3 has become a hot spot in the field of photocatalysis because of its narrow band gap, high stability and low price. In order to develop the high performance Fe2O3 photoanodes materials, many studies focused on the energy band position, conductivity and photogenerated the hole diffusion length. This review summarized the preparation techniques (hydrothermal method, spray pyrolysis, chemical vapor deposition, atomic layer deposition, etc), modification methods (“junction” construction, doping, morphological control, ect) and modified hydrogen production of the Fe2O3 photoanodes materials, the challenges and opportunities in this promising research area were proposed.